Grease extractor for kitchen ventilating systems



Jan. 20, 1970 DE WITT H. DOANE 3,

GREASE EXTRACTOR FOR KITCHEN VENTILATING SYSTEMS Filed Oct. 2, 1967 2 Sheets-Sheet 1 ENveNofl EWW'T H, OANE Avws.

Jan. 20, 1970 DE WITT H. DOANE 3,

GREASE EXTRACTOR FOR KITCHEN VENTILATING SYSTEMS Filed Oct. 2, 1967 2 Sheets-Sheet 2 Imam-0R 18!? Dawn"!- H.0oms 43 3" W y, Wade QM United States Patent US. Cl. 55-242 8 Claims ABSTRACT OF THE DISCLOSURE A flameproof grease extraction system for removing grease, oiland other condensable contaminants from a vaporous exhaust stream in a kitchen ventilating system. The grease extraction system comprises a housing with an entranceway for receiving the exhaust stream, an outlet for discharging the exhaust stream into a duct which contains a blower or fan for drawing the exhaust stream through the extraction system, and internal baflie means for guiding the exhaust stream along a predetermined path designed to provide the extracting action. The battle arrangement includes an entrance baflle which extends rearwardly from-the top of the entranceway for deflecting the entering exhaust stream rearwardly over the bottom wall of the extractor housing. A second baflle means then deflects the exhaust stream upwardly from the bottom wall around the rearward edge of the entrance baflie means and forwardly over the top of the entrance baflle means toward the front'w'all. Third baffle means then deflects the exhaust stream rearwardly from the front wall and down along the rear side of the second baffle means to the bottom wall, and then upwardly again between the-rear side of the third baflle means and the rear wall of the housing. A- drain means is provided in the bottom wall of the housing for receiving the extracted grease and oil which is deposited on the internal surfaces of the system, and which runs downwardly thereover due to the heating of the internal surfaces by the adjacent cooking surface.

The present invention relates generally to kitchen ventilating systems and, more particularly, to an improved grease extraction system for extracting condensable contaminants such grease and oil from the vaporous exhaust stream in a kitchen ventilating system before the exhaust stream is discharged to the atmosphere.

It is the general aim of the present invention to provide an improved grease extraction system which provides significantly improved grease extraction combined with the ability to prevent the passage of flame through the extraction system. A more particular object is to provide such a grease extraction system which is capable of extracting over 9'9% of the condensable contaminants from a vaporous exhaust stream, while providing 100% efficiency in preventing the-passage of flame through the extraction system. A related object isto provide an extraction system which combines such performance characteristics with arelatively low pressure drop between the inlet and outlet ends of the system,-thereby minimizing the power requirements on thebloweror-other air-moving device. .-i i

It is another object of the present invention to provide an improved grease extractionsystem of the'foregoing type which can be manufactured efl-iciently and economically from relatively few low cost parts. A related object is to provide such .agreaseextraction system in which all the parts can be formed by conventional cutting and stamping operations, and which requires nomoving parts.

A further object of this, invention is to provide an improved grease extraction system of the type described 3,490,206 Patented Jan. 20, 1970 above which permits the eflicient utilization of fluid washing and/ or fire extinguishing systems with manual or automatic control. In this connection, it is another object of the invention to provide such a grease extraction system which can be completely flushed with washing or fire extinguishing fluid from a single internal distribution line.

Still another object of the present invention is to provide such an improved grease extraction system which is continuously self draining so as to prevent the accumulation of extracted grease and oil and other contaminants therein. Thus, a more particular object of the invention is to provide such a system which not only effectively extracts the condensable contaminants from a vaporous exhaust stream, but also transports the extracted materials rapidly and efliciently out of the path of fluid flow.

It is a still further object of the invention to provide such an improved grease extraction system which improves the longevity of the downstream portions of the ventilating system by extracting substantially all the condensable contaminants from the exhaust stream before it enters the main duct work, and by preventing the passage of flame into the duct. Yet another object of the invention is to provide such a grease extraction system which provides convenient access to the internal portions thereof for inspection purposes and the like.

Other objects and advantages of the invention will become apparent from the following detailed description and upon reference to the accompanying drawings, in which:

FIG. 1 is a perspective view of a conventional cooking range and its associated ventilating system including a grease extraction system embodying the present invention;

FIG. 2 is an enlarged vertical section of the grease extraction system shown in FIGURE 1;

FIG. 3 is a top plan view of the grease extraction system of FIGURE 1 with a fragment thereof broken away to show the internal structure;

FIG. 4 is a section taken along line 44 in FIGURE 2; and

FIG. 5 is an enlarged front elevation of one of the lower nozzle assemblies connected to the fluid supply line shown in FIGURE 1.

While the invention will be described in connection with certain preferred embodiments, it will be understood that it is not intended to limit the invention to these particular embodiments. On the contrary, it is intended to cover all alternatives, modifications, and equivalent arrangements as may be included within the spirit and scope of the invention as defined by the appended claims.

Turning now to the drawings, in FIGURE 1 there is shown a cooking range 10 having a cooking surface 10a from which hot fumes laden with grease and oil vapors and other condensable contaminants rise upwardly toward a canopy or hood 11 which projects out over at least a portion of the cooking surface 10a. The hood 11 is mounted on a grease extraction housing 12 which includes a top wall 13, a rear wall 14, anda 'pair'of'side walls 15 and 16. The front wall of the cabinet is stepped or indented at the bottom so as to form a protruding upper portion 17a and a recessed lower portion 17b. The bottom wall of the housing is correspondingly stepped to form a forward portion 18a extending between the two front wall portions 17a, 17b, and a rearward portion 18b extending between the rear wall 14 and thelower front wall portion 17b.

As the hot, grease-laden fumes rise upwardly beneath the hood 11, they are drawn into the housing 12 and on through the grease extraction system therein by means of fan or blower 19 (FIG. 2) which is mounted within a flue or vent duct 20 connected to the outlet of the housing 12. For the purpose of closing the duct 20 in the event of a fire in the ventilator system, a fire door 21 is pivotal- 1y mounted in the duct and held open by a conventional wire including fusible links adapted to fuse and thereby release the fire door 21 for movement to its closed position in response to a predetermined temperature. The rate at which the exhaust stream is drawn through the extraction system is determined by the blower 19, a typical flow rate being 300 cubic feet per minute perlineal foot of ventilator (c.f.m.). As the exhaust stream leaves the housing 12, it is conducted via the duct 20 to an appropriate outlet for discharge to the atmosphere. It will be understood that the blower 19 represents only one example of a suitable device for drawing the exhaust stream through the grease extraction system, and that the invention is equally applicable to ventilating systems employing other air moving devices, such as power roof ventilators and the like.

In accordance with the present invention, the front wall of the housing 12 forms a vertically restricted, horizontally elongated entranceway for admitting the vaporous exhaust stream into an internal grease extraction system comprising an entrance baflle means extending rearwardly from the top of the entranceway for deflecting the entering exhaust stream rearwardly over the bottom wall of the housing, second baffle means for deflecting the exhaust stream upwardly from the bottom wall of the housing around the rear edge of the entrance batfle means and forwardly over the top of the entrance baflle means toward the front wall of the housing, and third baffle means for deflecting the exhaust stream rearwardly from the front wall of the housing and downwardly behind the second baflle means to the bottom wall of the housing, and then upwardly again between the rear side of the third baflle means and the rear wall of the housing. Thus, in the particular embodiment illustrated in the drawings, the hot grease-laden fumes are drawn into the housing through an entranceway formed on the upper portion 17a of the front wall just slightly above the forward portion 18a of the bottom wall. The entranceway 30 is relatively narrow or restricted in the vertical direction, so as to increase the velocity of the exhaust stream as it enters the housing, but is elongated horizontally so as to extend continuously between the two side walls 15, 16, to insure the collection of vapors across the full width of the cooking surface.

As the hot exhaust stream enters the grease extraction system through the entranceway 30, it is deflected rearwardly over the adjacent bottom wall 18a by means of an entrance baflle 31 formed as an integral part of the front wall 17a, and inclined downwardly toward the bottom wall 18a at an angle of 18 from the horizontal. The constriction formed by the entrance baffle 31 on the top, and the bottom wall 18b, and front wall 17a on the bottom sharply reduces the cross-section of the exhaust stream, with a corresponding increase in the fluid velocity. As the velocious exhaust stream passes rearwardly over the bottom wall 18a, it is deflected upwardly past the rearward edge of the entrance baflle 31 by means of an upwardly projecting baflle 32 which is joined at its lower end to the bottom wall 18a and extends upwardly past the rear edge of the entrance baffle 31 and spaced therefrom. The upper end of the vertical baflle 32 terminates in a forwardly projecting baflle 33, which extends forwardly at least as far as the rearward edge of the entrance baflie 31, and spaced upwardly therefrom, for deflecting the exhaust stream forwardly over the top of the entrance baffle toward the front wall 17a.

It can be seen that the combination of the entrance baffle 31, the bottom Wall 18a, and the baflles 32 and 33 effect a 180 reversal in the direction of flow of the exhaust stream. That is, the exhaust stream flows rearwardly beneath the entrance baffle 31 as it enters the housing, and is then quickly reversed so as to flow toward the front of the housing on the top of the entrance baffle 31. The centrifugal action resulting from this flow reversal causes a substantial portion of the condensable grease and oil entrained in the exhaust stream to be deposited or plated out on the surrounding walls, thereby providing an initial extraction stage. The extracting action in this initial stage is enhanced by an increase in the volume of the extraction chamber in which flow reversal is effected. More particularly, the volume of the chamber formed by the bottom wall 18a and the baflles 31, 32, 33 increases in the area adjacent the juncture of the bottom wall 18a and the vertical baflie 32, thereby causing the exhaust stream to expand simultaneously with the reversal in its direction of flow, with resultant condensation and agglomeration of the grease and oil vapors therein. A smaller secondary expansion chamber is formed in the area adjacent the junction of the baffles 32 and 33, with similar effect.

In order to insure that a maximum amount of grease and oil is removed in the initial extraction chamber, th forward end of the baflle 33 is bent transversely to the direction of fluid flow so as to form a small lip or trap 33a which collects a substantial portion of the grease and oil which is still entrained in the exhaust stream. Since the trap 33a is located at the outer periphery of the turning exhaust stream, it is in the area of the greatest concentration of remaining grease and oil particles for maximum efficiency.

As the exhaust stream moves forwardly above the entrance bafile 31, its direction of flow is reversed a second time by the deflecting action of the front housing wall 17a and a rearwardly projecting baffle 35 joined to the front wall and extending rearwardly therefrom a spaced distance above the forwardly projecting baflle 33. Moreover, a pair of expansion chambers are again provided in the course of this flow reversal, namely in the areas adjacent the junction of the entrance baflle 31 and the front wall 17a, and adjacent the juncture of the front wall 17a and the rearwardly projecting baflle 35. The resulting expansion of the velocious exhaust stream and the concurrent centrifugal action from the turn in the fluid flow again produces a heavy deposition or plating out of the agglomerated grease and oil on the surrounding walls.

As the exhaust stream flows rearwardl between the baflles 35 and 33 and past the vertical baffle 32, it is deflected downwardly along the rear side of the baflle 32 by means of a downwardly projecting baflle 36 joined to the upper baffle 35 and extending downwardly past the rear edge of the baflle 33. In the illustrative embodiment, the baffle 36 extends downwardly past the entire length of the bafiie 32 and terminates at a point below the bottom wall 18a of the forward portion of the housing, but above the bottom wall 18b of the rear portion of the housing. Consequently, the exhaust stream flows downwardly through the conduit formed by the depending baflie 36 on the rear side, and the baflie 32 and the front wall 17b on the front side, until it reaches the bottom wall 18b of the rear portion of the housing. At the lower end of the baffle 36, the flow direction of the exhaust stream is again reversed by the combined action of the front wall 17b, the bottom wall 18b, and the rear wall 14. Another expansion chamber is also provided in the area between the bottom edge of the baffle 36 and the bottom wall 18b, which area is substantially wider (FIG. 2) than the area between the baffle 36 and the front wall 17b. To further restrict the exhaust stream just before it enters this expansion chamber, a forwardly projecting flange 36b is formed on the bottom edge of the baflle 36.

As the exhaust stream passes the flange 36b and is deflected rearwardly beneath the flange and then up along the rear side of the depending baifle 36, the combined centrifugal action and expansion once again deposits condensed grease and oil on the surrounding side walls. The remaining exhaust stream, which is composed primarily of non-condensable materials at this point, flows on up between the rear wall 14 and the depending baffle 36 into the region above the bafile 35 where it is discharged through an exit opening in the top wall 13 into the exhaust duct 20. The relatively large unrestricted area between the baflie 35 and the top wall 13 permits the exhaust stream to expand again just prior to its discharge from the extraction system, thereby cooling the stream before its entry into the duct and minimizing the pressure drop along the rear wall 14.

In order to facilitate the flow reversal around the lower end of the depending baflie 36, with a minimum of turbulence, a pair of elongated deflector plates 37, 38 are mounted in the corners of the extraction chamber formed below the baffle 36. More particularly, a front deflector plate 37 is mounted at an angle of 45 across the corner formed by the front wall 17b and the bottom wall 18b, and a rear deflector plate 38 is mounted at the same angle across the corner formed by the rear wall 14 and the bottom wall 18b. These deflector plates 37, 38 guide the exhaust stream smoothly around the lower end of the baflie 36, so as to avoid the creation of turbulence in the front and rear corners beneath the deflector plates.

It has been found that the downward flow of the exhaust stream effected by the downwardly projecting baffle 36, following the initial double flow reversal, with the further abrupt flow reversal at the bottom of the downward travel, has the dual effect of (l) removing any remaining condensable or solid contaminants in the exhaust stream, and (2) preventing any flame that might leak through the initial extraction stages from continuing on through the extractor. While it is not intended to limit the present invention to any specific theory, it is believed that the improved extracting action of the final down-up stage is due to the combined effect of the concurrent expansion and centrifugal action described previously, and the impingement of the contaminants on the bottom wall of the extractor (including the deflector plates 37, 38) due to the gravitational forces acting on the contaminants during the downward leg of the flow pattern just prior to the final flow reversal. In actual tests of the illustrative system (to be described in more detail below), extraction efl'iciencies of over 99% have been obtained with reliable repeatability, and severe flame tests have demonstrated that it is virtually impossible for flame to penetrate beyond the final down-up extraction stage.

In order to minimize the pressure drop across the extraction system, thereby minimizing the power requirement on the blower or fan which draws the exhaust stream through the extraction system, it is preferred to have the extraction system gradually expand or open up between the inlet and outlet ends thereof, i.e., in the direction of fluid flow. Thus, in the illustrative embodiment, the restriction in the initial extraction stages are somewhat smaller than those in the final extraction stages. More particularly, the restrictions between the entrance baffle 31 and the flange 34 on the bottom, the baflie 32 on the rear, and the flange 33a on the top, are all slightly smaller than the restrictions between baflies 33 and 35, baflies 32 and 36, and baflie 36 and rear wall 14. With this particular arrangement, typical static pressures measured at points A, B, C, D, and E in FIGURE 2 (such points being spaced along the path of fluid flow) are 0.48, 0.75, 0.84, 0.82, and 0.85 inch, which indicates an extremely low pressure drop across the entire system. It has been found that static pressures as low as 0.8 inch can be attained at the outlet of the extraction system.

Since the grease extractor housing is located directly over or adjacent to the cooking surface v11, the surfaces of the housing walls and the internal baffles on which the extracted grease and oil is deposited, are at a sufiiciently high temperature to cause the deposited material to remain in a fluid condition and run down to the bottom of the housing. The grease which runs down the front wall 170, the entrance baflle 31, the understide of the baflie 33, the front side of the baffle 32, and the bott m wall 18a all collects at the juncture of the bottom wall 18a and the vertical baffle 32, where a pair of drain openings 40 (FIGS. 1 and 2) are formed at opposite ends of the bottom of the baffle 32 to conduct the grease therethrough. The bottom wall 18a preferably slopes downwardly from front to back, as illustrated in FIGURE 2, to insure that all of the grease and oil deposited thereon runs rearwardly to the drain openings 40, thereby avoiding any substantial accumulation of condensed materials on the bottom of the initial extraction chamber. As the extracted liquids drain through the openings 40, they run downwardly along the inside of the front wall 17b onto the lower bottom wall 18b, where the extracted liquid is discharged from the housing through an opening 42 into a drain line 43 leading to an external receptacle. While experience has shown that the relatively small drain h les 40 do not permit any significant portion of the exhaust stream gases to pass directly through the baflle 32, a drain line with a liquid trap may be connected to the drain holes 40 so that the liquid which collects in the trap serves as a vapor barrier to prevent any portion of the exhaust stream from passing directly through the baffle 32. It will be appreciated from the foregoing description that the continuous drainage of the extracted liquids from the front side of the vertical bafiie 32 into the region behind the baffle 32, has the advantage of moving these materials into a zone of high extraction efiiciency and fire safety. Consequently, any material that might become reentrained in the exhaust stream is quickly extracted again in the final extraction stage below the downwardly projecting baflie 36.

It can be seen from the foregoing description that the illustrative grease extraction system is continuously self draining, so that the extracted liquids are quickly removed from the interior of the extraction system to prevent or minimize re-entrainment thereof in the vaporous exhaust stream. No matter where the extracted grease and oil are deposited within the housing, they are free to run downwardly over smooth, uninterrupted surfaces to the drain openings provided for removing the extracted liquids to an external receptacle. Similarly, this continuous selfdraining construction also facilitates cleaning of the extraction system, since cleaning solutions can run freely through the extractor in the same manner as the extracted liquids, and over the same surfaces. The same is true of fire extinguishing liquids, in the event that it is desired to include a fire extinguishing system in the extractor.

In the particular embodiment illustrated, the drain openings 40 are shown as being located adjacent the side wall 15, while the bottom drain opening 42 is located in the center of the bottom wall 18b. However, it will be appreciated that the locations of these drain openings may be changed without departing from the spirit and scope of this invention, since the extracted liquids will find their way to the drain openings regardless of where they are located along the length of their unit. Also, it may be desired to provide more than one upper and/or lower drain opening, or to vary the size thereof, for different applications. It has been found that it is not necessary to slope the bottom walls 18:: and 18b in the transverse direction toward the drain openings 40 and 42, respectively, but such slopes could be built into the system to enhance the draining action if desired.

In accordance with a further aspect of this invention, the grease extraction system is designed so that a single fluid supply line can be utilized to dispense fluid for cleaning and/or fire extinguishing purposes, into all the internal spaces of the extraction system. Thus, in the illustrative embodiment, a single fluid supply line 50 is mounted on top of the uppermost baffle 35, and is provided with three series of dispensing nozzles 51, 52, and 53. The first series of nozzles 51 project slightly below the baffle 35 and are oriented to discharge fluid into the forward region of the extractor between the front wall 17a and the baffles 33 and 32. The second series of nozzles 52 also project below the baffle 35, and are oriented to discharge fluid into the intermediate region between the baflies 32 and 36, while the third series of nozzles 53 project above the baifle 35 and are oriented to discharge fluid into the rear region between the rear wall 14 and the baflle 36. Since the fluid is normally supplied under a substantial pressure, it tends to splash onto all the surfaces in these regions, and then runs downwardly over such surfaces to the drain openings 40 and 42 for removal from the extractor housing in the same manner described above in connection with the extracted materials.

It can be seen that the design of the extraction system enables a single strategically located fluid supply line to supply fluid to all the internal surfaces of the system. Thus, the interior of the extractor system can be periodically cleaned by feeding a cleaning solution into the supply line 50, with the cleaning solution being distributed by the nozzles 5153 onto all the internal surfaces of the various walls and baffles to prevent the undesirable accumulation of extracted materials thereon. Such cleaning may be initiated manually or automatically by simply providing an appropriate valve to control the supply of fluid to the supply line 50. Moreover, the same system may be utilized to dispense a fire extinguishing fluid, in either liquid or gas form. As in the case of the cleaning solution, the fire extinguishing fluid is quickly and efliciently distributed from the single supply line throughout the entire interior of the extraction system so that any flame existing therein will be quickly smothered.

As an illustration of the superior performance characteristics of the extraction system provided by this invention, a typical installation was subjected to severe grease extraction and fire prevention tests. Thus, in a first grease extraction test, a system identical to that illustrated in the accompanying drawings was utilized. The extraction housing was 3 feet in length, with rear wall height of 2 feet. The width of the top wall, between the front and rear walls, was 1 foot, and the height of the upper portion of the front wall, between the bottom wall portion 18a and the top wall 13, was about 14 inches. The proportions and relative sizes of all the other parts were as shown in the attached drawings. To determine the amount of grease extracted from the exhaust stream passed through the extraction system, a filter was mounted in the exhaust duct 10 inches above the top of the extractor housing, and was covered with cheesecloth to collect any grease not removed in the extraction system. The cloth was weighed before being placed over the filter. The extraction system was preheated with two 250-watt heat lamps for a period of one hour to simulate the heating which would normally be provided by the cooking surface. The ventilator system utilized in the test, including the blower in the exhaust duct, was set up to exhaust at a rate of 300 cubic feet per minute per lineal foot. In order to provide a heavily contaminated exhaust stream, SAE 5 lubricating oil (345 F. flashpoint, 0.907 specific gravity) was sprayed continuously toward the entranceway of the extraction system from aerosol cans. Two aerosol oil cans were sprayed continuously for 9 minutes, and the total amount of oil injected during this period was 37.78 ounces, which is approximately the amount of grease and oil that is normally generated in a two-week cooking period in a typical commercial installation. At the end of the test period, i.e., after the oil spraying was terminated, the ventilating system was shut offand the filters removed for the purpose of weighing the cloth thereon to determine the amount of oil passed through the extraction system. The weight of the cloth before the test was 0.9 ounce, and the weight after the test was 1.1 ounces, indicating that 0.2 ounce of oil passed through the extraction system. Based on the 37.78 ounces of oil fed, the total extraction efficiency was 99.47%. The static pressure at the outlet of the extraction system was also measured during the test, and found to be 0.85 inch.

In a second grease extraction test, the grease extraction system utilized was similar to that described in the example above, except that the extraction housing was five feet in length, and the rear wall height was 57 inches. The reason for the increase in height was to permit floor mounting of the extraction system, so the entire height increase was in that portion of the unit below the forward bottom wall 18a. That is, the rear wall 14, the lower front wall 17b, and the bafl le 36 were simply made long enough to extend down behind the cooking range so that the rear bottom wall 18b could rest on the floor behind the cooking range. The proportions and relative sizes of all the other parts, i.e., above the forward bottom wall 18a, where the same as shown in the attached drawings. The test was conducted in the same manner described above, except that the blower was set to exhaust at a rate of 275 c.f.m., because of the larger size of the unit, and a total of 48.15 ounces of SAE 5 lubricating oil were fed into the system over a 10.5- minute test period. Tow aerosol oil cans were sprayed continuously for the first nine minutes (total of 14 cans), after which one can was sprayed for 1.5 minutes. The weight of the filter cloth before the test was 1.73 ounces, and the weight after the test was 1.38 ounces, indicating that 0.35 ounce of oil passed through the extraction system. Based on the 48.15 ounces of oil fed, the totat extraction efiiciency was 99.30%. The static pressure at the outlet of the extraction system was also measured during the test and found to be 0.8 inch.

In order to test the fire-suppressing ability of the extraction system described above, it was subjected to two different types of tests, namely a dry fire test and a wet fire test. In the dry fire test, a pan 4 inches high, 30 inches long, and 9 inches wide was filled to a depth of two inches with a mixture of SAE 20 motor oil and gasoline. This mixture was preburned for approximately one minute, and then placed slightly below the entranceway to the extraction system with the system operating at an exhaust rate of about 300 c.f.m. In order to measure the internal temperatures ofthe extraction system during the fire test, thermocouples were mounted at four internal points spaced along the fluid flow path, as follows: (1) directly below the entrance bafile just inside the entranceway, (2) below the bottom edge of the battle 36 at a point between the front wall 17b and a projection of the baifle 36 and about midway between the bottom of the bafiie 36 and the bottom wall 18b, (3) midway between the baflie 36 and rear wall 14 at about the same elevation as the baffle 33, and (4) just below the center of the outlet opening in the top wall of the housing. In addition, an inspection window of heat resistant glass was mounted in the front wall of the plenum or duct just above the top wall of the extraction housing to permit observation of the exhaust stream discharged from the extractor. The temperatures measured two minutes after the flaming pan was placed below the entranceway of the extraction system, with considerable flame penetrating into the entranceway, were as follows:

F. Location #1 700 Location #2 500 Location #3 500 Location #4 460 The fire was allowed to burn for approximately five minutes, and at no time during this test period was there any flame visible through the observation window, thereby indicating that the extraction system continuously suppressed the flame which entered the front portion of the system.

In the wet first test, 16.05 ounces of SAE 5 lubricating oil were sprayed from aerosol cans directly into the entranceway with the blower running at an exhaust rate of about 300 c.f.m. In addition, about one pint of SAE 20 motor oil was then poured into the entranceway, and another pint of the same oil was poured down along the rear side of the downwardly projecting baffle 36. Visual examination indicated that the entire interior of the extraction system was coated with either'the lubricating oil F. Location #1 1000 Location #2 650 Location #3 600 Location #4 640 It could be seen that the flames drawn into the entranceway ignited the oil on the internal surfaces visible through the entranceway, but at no time could any flame be seen through the observation window, throughout the five minute period that the fire was allowed to burn. The fire was then extinguished, more oil added to the pan and poured into the entranceway, and the fire started again. As before, flames were drawn into the entranceway, but there was no flame visible through the observation window, thereby indicating that the flame could not travel through the baflie system.

In addition to the significant improved performance characteristics, the extraction system provided by this invention can also be efficiently manufactured at a relatively low cost and at high production rates with excellent quality control. Thus, the entire system illustrated in the drawings can be fabricated from a total of seven parts, all of which are formed by simple cutting and stamping operations. No machining whatever is required. A first part forms the top wall 13; a second part forms the rear wall 14 and the two side walls 15 and 16; a third part forms the bottom wall 18b, the front wall 1717, the bottom wall 180, and the flange 34; a fourth part forms the top front wall 17a; a fifth part forms the baflles 32 and 33; a sixth part forms the baffles 35 and 36; and a seventh part forms the hood 11 including the depending side walls thereof. If it is desired to include the deflector plates 37 and 38, of course, two additional parts are required. Moreover, these parts can be assembled as efficiently as they are formed, by a few simple welding operations.

Furthermore, by mounting the front panel 17a in a removable manner, such as by the use of removable screws 60 shown in the drawings (FIGS. 2 and 4), a major portion of the interior of the extraction system can be quickly and conveniently exposed, for inspection purposes for example, by simply removing the one front panel. Such inspection might be required, for example, by building codes or other requirements. The convenient access provided by the removable front panel also facilitates installation and maintenance of the internal fluid dispens ing system for cleaning and/ or fire extinguishing purposes, as described previously. Since the fluid supply line 50 is mounted just inside the front wall of the extractor housing, it is fully exposed as soon as the front panel has been removed.

As demonstrated by the two grease extraction tests described previously, the extraction system provided by this invention can be varied in length, to accommodate different types of mounting arrangements for example, by simply varying the length of the rear wall 14, the lower front wall 17b, and the depending baflle 36, without affecting the performance of the system. It will also be understood that the extraction system can be fabricated without the hood unit 11, which is made from a single sheet of metal in the illustrative embodiment, to permit custom installation of the extraction system in different types of hoods and ventilator systems.

As can be seen from the foregoing detailed description, this invention provides an improved grease extraction system with significantly improved grease extraction characteristics combined with the ability to prevent the passage of flame through the extraction system. As demonstrated by the above examples, the invention provides a grease extraction system which is capable of extracting over 99% of the condensable contaminants from a vaporous exhaust stream, while providing 100% efliciency in preventing the passage of flame therethrough. Furthermore, these performance characteristics are achieved with only a minimal pressure drop across the extraction system, thereby minimizing the power requirements on the blower. This improved system can also be manufactured efficiently and economically from relatively few low cost parts, all of which can be formed by conventional stamping and cutting operations. Moreover, the improved extraction system permits the eflicient utilization of fluid washing and/or fire extinguishing systems and, indeed, the entire internal structure of the extraction system can be completely flushed with washing or fire extinguishing fluid from a single internal distribution line. The system is also continuously self draining so as to prevent the accumulation of extracted grease and oil therein. Because of the high level of extraction efficiency, the system of this invention improves the longevity of the downstream portions of the ventilating system. The preferred structure has the further advantage of providing convenient access to the internal portion of the extraction system for inspection purposes and the like.

I claim as my invention:

1. A flameproof grease extraction system for removing grease, oil and other contaminants from a vaporous exhaust stream in a kitchen ventilating system, said extraction system comprising the combination of a housing having top and bottom walls, front and rear walls, and a pair of side walls, said front wall forming a restricted, horizontally elongated entranceway for receiving the vaporous exhaust stream, entrance baflle means extending rearwardly from the top of the entranceway for deflecting the entering exhaust stream rearwardly over the bottom wall, second baflie means for deflecting the exhaust stream upwardly from said bottom wall around the rearward edge of said entrance baffle means and forwardly thereover toward said front wall, and third baflle means for deflecting the exhaust stream rearwardly from said front wall then downwardly along the rear side of the second batfle means to said bottom wall and finally upwardly between the rear side of the third baffle means and said rear wall, outlet means adjacent the top of said housing and drain means in the bottom wall of said housing on the rear side of the second baflle means for receiving the extracted contaminants deposited on said baffle means and housing walls and conducting same out of the housing, and further drain means at the bottom of said baffle means for conducting extracted contaminants from the front side of the second baflle means rearwardly thereof to provide access of said contaminants to said drain means.

2. A flameproof grease extraction system as defined in claim 1 which includes fluid dispersing means mounted within said housing and including first nozzle means for spraying fluid into the spaces between said entrance baflle means and said second bafile means and between said second baffle means and said third bafile means, and second nozzle means for spraying fluid into the space between said third baffle means and the housing walls.

3. A flameproof grease extraction system as defined in claim 2 in which said first and second nozzle means are supplied with fluid from a common fluid distribution means in said housing.

4. A flameproof extraction system as defined in claim 1 wherein the rear portion of said bottom wall behind said second bafile means is disposed a substantial distance below the forward portion of said bottom wall on the front side of said second bafiie means.

5. A flameproof grease extraction system as defined in claim 4 in which the front wall of said housing interconnects the forward and rear portions of said bottom wall, the interconnecting portion of said front wall being vertically aligned with the lower edge of said second baffle means.

6. A flameproof grease extraction system for removing grease, oil and other contaminants from a vaporous exhaust stream in a kitchen ventilating system, said extraction system comprising the combination of a housing having top and bottom walls, front and rear walls, and a pair of side walls, said front wall forming a vertically restricted, horizontally elongated entranceway adjacent said bottom wall for receiving the vaporous exhaust stream, an entrance baflle joined to said front wall and extending rearwardly from the top of said entranceway for deflecting the incoming exhaust stream rearwardly over said bottom wall, an upwardly projecting baflie joined to said bottom wall and extending upwardly past said entrance baflie and spaced from the rearward edge thereof for deflecting the exhaust stream upwardly past the rearward edge of said entrance baflie, a forwardly projecting baffle joined to said upwardly extending baflie and extending forwardly at least as far as the rearward edge of said entrance bafiie and spaced from said front Wall for deflecting the exhaust stream forwardly over said entrance baffle and upwardly along said front Wall, a rearwardly projecting bafiie joined to said front wall and extending rearwardly beyond said forwardly projecting baffle and spaced above the upper surface of said forwardly projecting baflie for deflecting the exhaust stream rearwardly over said forwardly projecting baffle, a downwardly projecting baflle joined to said rearwardly projecting baflie and extending downwardly past said forwardly projecting baflle and spaced from the rear side of said upwardly projecting baffle, said downwardly projecting bafiie overlapping at least a major portion of said upwardly extending baffle for deflecting the exhaust stream downwardly behind said upwardly extending baflie to said bottom wall, said downwardly projecting baffle also being spaced from said rear wall so that the exhaust stream deflected downwardly along the front side of said downwardly extending bafile continues around the lower edge thereof and upwardly along the inside of said rear wall and drain means adjacent the bottom Wall of said housing on the rear side of said upwardly project? ing baffle means for receiving the extracted contaminants deposited on said baffle means and said housing walls and conducting same out of the housing, at least one drain means at the juncture of said upwardly projecting baflie means and said bottom wall for conducting extracted contaminants from the front side of said bafiie means to the rear thereof to provide access of said contaminants to said drain means.

7. A flameproof grease extraction system as defined in claim 6 which includes fluid dispensing means mounted within said housing and having first nozzle means projecting below said rearwardly projecting bafiie for spraying fluid downwardly into the various spaces between said front wall and said downwardly projecting baffle, and second nozzle means projecting above said rearwardly projecting baffle for spraying fluid into the space above said rearwardly projecting baffle and behind said downwardly projecting baffle.

8. A flameproof grease extraction system as defined in claim -6 wherein the rear portion of said bottom wall behind said upwardly projecting baflle is disposed a substantial distance below the forward portion of said bottom wall on the front side of said upwardly projecting bafile, and said downwardly projecting baffle extends below the forward portion of said bottom wall for deflecting the exhaust stream down to the rear portion of said bottom wall.

References Cited UNITED STATES PATENTS 640,796 1/1900 Neuhs 261108 1,917,857 7/1933 Searless 5S346 2,373,330 4/1945 Nutting 26l108 2,385,077 9/1945 Harker et al. 241 2,393,957 2/ 1946 Baumgartner.

2,536,998 1/1951 Newcomb et al. 55-442 2,873,816 2/ 1959 Umbricht et al 55241 3,018,847 1/ 1962 Stanly 261-111 3,060,833 10/1962 Pledger. 3,075,336 1/1963 Hays 55-442 3,242,652 3/ 1966 Malenchini. l 3,304,572 2/1967 Wendel 55217 3,324,629 6/1967 Graswich et al.. 55240 3,370,404 2/1968 Leeper 55240 3,376,804 4/1968 Marks 55-442 3,393,497 7/1968 Donnelly 55-472 HARRY B. THORNTON, Primary Examiner BERNARD NOZICK, Assistant Examiner U.S. Cl. X.R. 

